Flow controller reset



Oct. 12, 1948.

w. J. HUGHES FLO CONTROLLER RESET' 2 Sheets-Shea 1 Filed Feb. 4, 1944 ZNVEN TOR.

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I 1 INVENTOR.

WaZZerJHzghfi, I BY Patented Oct. 12, 1948 I i I UNITED STATES PATENT mm; I FLOW COiidfitfZERRI-JSET i. c c

Walter J. Hughes, Chicago, Ill., assiznor to Infllco IncorporatedyChicago, 111., a corporation of Delaware Application February 4, 1944, Serial No. 521,096 11 Claims. (01. arc-122.1)

My invention relates generally to fluid flow controllers, and particularly to a device for use with such fluid flow controllers for terminating or modifying rate of flow, as fixed by such controllers, in accordance with some independent function such as termination of flow through such controller, the filling of a clearwell, and the like.

More particularly the invention relates to a device for modifying or resetting a controller of the type adapted to regulate a flow of fluid through a v conduit for the purpose of maintaining a uniform flow therethrough in spite of variations in pressure resistance in the system, as, for example, a flow controller to maintain the flow 'of water through a gravity filter bet. at a uniform rate. The invention has particular: utility-in resetting such a control device to gradually close the control valve after another valve inthe line has been used to shut off the flow therethrough, or when some outside condition arises, such as the filling of a filtered liquid basin to a predetermined level, or both, and to gradually reopen the control valve, starting from a closed position,.when the flow is again permitted.

A principal object of my invention is to provide hydraulic means for resetting the controlling element of such controllers when the flow therethrough is cut off by closing a valve in the line regulated by the controller. Ordinarily, a direct acting controller opens its valve or controlling element to wide o'penposition when flow is restricted or cut oil by any means external to the controller. Therefore when flow is again established, the controller must necessarily start action with its controlling valve or element'in wide open position. Objection to starting'the controlling action from a wide open rather than a throttling position has arisen from the fact that there may be a. surge," or high rate of flow, at the start or until the controlling element can be moved to an effective position. It is, therefore, desirable that the controlling element be in a throttling position at the resumption of flow, so that the flow will be controlled up to the desired rate instead of down from a momentary higher rate than desired. Avoiding such initial surges, for instance in starting large filter bed units after they have been shut down for backwashing or reconditioning, avoids 1 disturbance of a freshly reconditioned and loosquire stopping and repeating the reconditioning process before service can be restored.

Another principal object is to provide an apparatus and process for modifying the set rate of flow of the controller by gradual reduction and "gradual restoration of the set rate with the rise and fall respectively of the level of liquid in the receiving chamber or clearwell into which the line controlled by such controllers discharges, and also effect substantiallyv complete shutoif when a predetermined high level is reached.

A still further object is to provide an apparatus and process for effecting gradual rate increases or decreases by substituting an increasing or decreasing portion of controller overall loss for a decreasing or increasing portion of the Venturi or controlling head responsive to flow.

Another object is to provide, .in a constant differential type of flow controller in which there are three different pressures (high pressure of inlet to Venturi tube and high pressure chamber of the actuator; low pressure-of the throat of the Ven-' substantially closed position when flow to the controller is cut off by substituting for the normal controlling head responsive to flow another head derived from overall loss sufliciently eflective to complete the closing action.

A further object of the invention is to provide a novel rate of flow controller which is sensitive to small variations in the rates of flow over a wide range of flows, in which friction is reduced to a minimum, and in which the-control valve will be completely closed upon the happening of either the termination of flow through the conduit or the rise of liquid to a predetermined, level in a basin connected to the system.

These, and other, objects of the invention will be apparent from the specification and drawings.

It has long been known to regulate a flow through a conduit, such as a filter efliuent pipe, from a pressure differential created by a Venturi tube. Such control is necessary, for example,

in the operation of a filter system in order to prevent a dangerous rush of water through the filter bed when the filter is first placed in operation. Early controllers of this type were subject to criticism in that they did not automatically close their fiow control valves upon termination of fiow through the efiluent. In early installations it was therefore necessary to provide manually operated valves for graduallyintroducing fiow through such a conduit. It was later proposed to provide attachments to such controllers such as counterweights, hydraulically operated pilot valves,- and the like, to automatically close the flow control valve upon termination of fiow through the conduit and to gradually permit the resumption of fiow when desired. Such structures were quite complicated and therefore expensive, and also required considerable adjustment from time to time. Also in many such types of apparatus there were required heavy counterweights, stufilng boxes and other inertia or friction producing parts which consumed a considerable amount of the pressure differential derived from the Venturi tube, thereby increasing the size and cost of the apparatus and also adversely affecting the operation of the controller since friction and inertia tend to prevent the beginning of a compensation movement of the controller and also to stop it short of completion.

In my improved controller the regulation of the rate of fiow is provided by a means which is entirely enclosed, thereby eliminating closely fitting rubbing surfaces or stufiing boxes, and also avoiding the use of heavy counterweights, thereby permitting the use of a smaller and lighter controller, and at the same time imparting great sensitivity over a wide range of flows. It is therefore an object of my invention to provide in a flow controller of the type actuated solely by a pressure differential of slight magnitude created by any suitable pressure differential creating means, such as a Venturi tube, a simple and inexpensive device which will automatically act to entirely close the control valve under certain conditions, such as the termination of fiow through the conduit itself or when the reservoir for receiving the flow becomes filled, or both such conditions.

In order to make the invention and its appli-- cation readily understood, it will be described in connection with a gravity type filtering system, such as used in municipal filtering plants, swimming pools and the like, although it is not limited thereto. Obviously the application of my invention will be suitable to many different types of fiuid flow controllers, but it will be shown and described, for purposes of exemplification, in connection with the constant differential" controller of the Patent No. 1,934,759, of Adelson, in connection with which it is particularly well adapted to secure the novel modification or resetting thereof.

Also, the device of this application is particularly adapted for use with so-called direct acting controllers, i. e., such types as employ substantially balanced control valvesand utilize selfcontained or direct valve actuating means, and will be shown in connection therewith. However, the present invention is not to be limited to the constant differential controller of Adelson or to a direct acting controller, as it might also be used in connection with other types of control devices.

My invention will be more readily understood by reference to the drawings, which form a part hereof and in which like reference characters designate similar elements.

' plant being an excellent illustration of such system. A gravity filter I0 is connected by means of effluent conduit II with a filtered water reservoir I2. It is well known that fiow through the filter I0 -must be carefully controlled to ,avoid damage thereto. It is also known that it is necessary to backwash and clean the filter from time to time and during such backwashing it is necessary to completely shut off the fiow through the conduit II. The conduit II is therefore provided with a shutoff valve I3 which may be operated by any suitable means such as a pilot valve I4 controlling fiow of pressure liquid to the hydraulic cylinder 22 which positions the shutoff valve I3. The volume of fiow through the conduit II is controlled by an automatic flow control valve I5. The control valve I5 is operated from a pressure differential created by a suitable resistance in the conduit, such as a Venturi tube I6. It is well known that the pressure differential which exists between the mouth I! and throat I8 of such a Venturi tube, can be used to position the flow control valve I5 by means of an actuator I9, to be more fully described hereafter, which is connected by a high pressure pipe 20 to the mouth I! of the Venturi tube and by low pressure conduit 2| to the throat I8 thereof.

Pressure differential responsive devices I9 are well known and ordinarily comprise a casing 30 commonly constructed from two concave castings 3I and 32 rigidly secured to each other. as at 33. A fiexible diaphragm 34 is rigidly held in the casing, as by clamping between the two sections at joint 33. This diaphragm divides the casing 30 into two chambers: a high pressure chamber 35 connected to a high pressure portion of the Venturi tube, such as the mouth II, by the high pressure conduit 20; and a low pressure chamber 36 connected by means of a low pressure conduit 2| to the throat I8, or other low pressure portion, of the Venturi tube I6. One end of a valve positioning rod 31 is attached by any suitable means, such as nuts 38 and 33 to a central portion of the diaphragm 34, and the other end is attached by any suitable linkage, such as a rotatable glanded shaft, not shown, to 2. preferably balanced type fiow control valve I5. Sueh connections with the fiow control valve I5 are well known, as for example, as shown in my prior patent, No. 2,307,273, and need not be described. Such construction permits the valve positioning rod 31 to be enclosed in a casing 40 in free communication with low pressure chamber 36 so that no tightly fitting stuffing boxes are necessary, whereby there is a minimum loss Of energy due to friction. I use a constant weight 43 on the diaphragm 34 for a pressure means normally tending to force the diaphragm into the high pressure chamber 35, this weight on the eflective area of the diaphragm being such as to oppose a specific portion of the normal Venturi head or pressure. I also prefer the type of diaphragm actuator in which the which in my preferred structure is more conveniently placed in a bypass 45 connecting the high pressure line 20 or high pressure chamber 35 with the low pressure line 2| or low pressure chamber 36. The fixed orifice 44, between the high pressure chamber 35 and the low pressure chamber 36, permits a constant flow from the high pressure chamber to the low pressure chamber, governed by the size of orifice 44 and the amount of weight placed effectively upon the diaphragm 34, thereby maintaining a constant diflerential between the two chambers.

This constant differential type oi controller has several advantages including lighter construction, effective operation on smaller pressure differentials, less loss due to inertia from heavy weights, and the like, which are not possible in old type controllers which had to be built and weighted for the maximum pressure differential that would exist between the unmodified pressures of the inlet and throat of the Venturi tube. I also have a rate setter valve 66 in the low pressure line 2!. In the constant differential type of controller there must be a second orifice or other restriction, which is placed between the low pressure chamber and the throat of the Venturi tube in order to cause a back pressure in the low pressure chamber 36. Obviously, without the second restriction, or orifice 56, the pressure in the low pressure chamber. and in pipe 2| would be that of the throat of the Venturi tube. By placing the rate setter valve 46 in the low pressure line, a back pressure is caused which increases the pressure in the low pressure chamber, so that there will be a lesser difference in pressures between the two pressure chambers 35 and 36. Thus the constant differential type of controller has and operates with and from, three different pressures: the high pressure of the inlet to the Venturi tube (transmitted to the high pressure chamber); the low pressure of the throat of the Venturi tube (only in thelow pressure pipe 2| between the Venturi tube and the rate setter valve 46) and an intermediate pressure (in low pressure chamber 36 and pipe 2i between the orifice 44 and the rate setter valve 46). In practice the second restriction is made adjustable in order to permit change of rates of flow at will. It is well known that the pressure pipes 20 and 2| are relatively large in order to minimize friction losses; the fixed orifice 44 is rather small; and therate setter valve adjustable from practically zero to'the sizeof the pipe. Thus the rate setter valve, which is seldom changed, must be tight fitting and requires considerable force to change. It is also well known that the value of the Venturi pressure differential (which is the sum of the difi'erentials in the bypass fiow due to the fixed orifice 44 and the rate setter valve 46), and thus therate of flow through the conduit I I may be readily adjusted by changing the size of the orifice in the ratesetter 46, thus changing the value of the drop in pressure therethrough. The fiow control system and the constant differential regulator are old, as shown by Adelson, and are not claimed herein.

My invention relates to an improved means whereby the pressure difierential responsive deoutside conditions. For example, my invention may be used to close the flow control valve I! automatically and promptly upon, closing the shutofi valve l3 so that, when the shutoff valve I3 is again opened, flow therethrough will be gradually resumed, thereby avoiding damage to the filter 10 which might result from an uncontrolled rush of water therethrough. My inven-. tion may also be used to provide an effective and efllcient means for actuating the pressure diflerential responsive device i9 to close the flow control valve l5 whenever the liquid level in the reservoir l2 reaches a predetermined point. Such controls can be secured by a variety of means which modify the intermediate pressure within low pressure chamber 36. For purposes of exemplification I shall describe one of. the simplest and most efi'ective of such devices, although other means will be obvious to those skilled in the art upon an understanding of my invention and the principles upon which it is based.

The control device of my invention'can be constructed within the actuatorcasing .30, but it usually is more simple to placeit in a separate casing 50 connected as hereinafter described to the actuator W. The supplemental casing 60 is divided into a high pressure flow passageii, a low pressure flow passage 52, a reset diaphragm chamber 63, and a waste chamber 54 by the partitions 56 and 66 and the flexible diaphragm 57, respectively. The low pressure fiow passage 52 communicates with the reset diaphragm chamber 53 through a constantly open orifice 58 and with the waste outlet chamber 54 through a waste port 69, preferably tapered to form a valve seat, which is shown in the drawing as closed by a tapered, or specially shaped plug valve 66. The high pressure flow passage 6| 'is connected to the high pressure chamber 35 of the actuator [9 by a pipe 6|. Similarly, the low pressure fiow passage 62 is connected to the low pressure chamber 38 of the actuator 19 by means of a pipe 62. An outlet pipe 63 leads from the waste compartment 64 to any suitable point of discharge, such as the eflluent line H, at a point below the flow control valve l6, as shown, or directly to the reservoir l2. The connection between the waste pipe 63 and the waste chamber 64 is provided with a substantially balanced type ofvalve 64 positioned by movement of the reset diaphragm 51. Any

balanced type of valve can'be used, but I have shown a valve unit which comprises valve seats 66 and 66 spaced a short distance apart and axially aligned one with another, and a valve comprising a cylindrical piston or stem 64a with a plurality of arcuate channels I00 formed therein. In such a valve, the tendency of fiow through one valve seat, such as 65, to open or close the valve is opposed by the fiow through the other valve seat 86, which forces will be of substantially equal magnitude and in opposite directions, thereby providing a balanced valve. One end of the valve 64, such as lfll, bears against, or is attached to, the flexible diaphragm 51, which operates to close valve 64., while a compression spring 81 tends to open it. It is preferred that the valve assembly be provided with stops such as "12 and I03 which prevent excessive movement in either direction. It is preferred that the stop I63 adjacent the spring end of the valve be so placed that the forcing of the valve 64 against that step will hold the valve in a fully closed position, while the stop I02 limits downward movemen to fully opened position. The valve 64 is normally closed when the plug'valve 60 is closed, due to higher pressure in chamber 53, than escapement pressure in line 63 and chamber 55. Thus the diaphragm acts to close valve 6 3 against the force of spring 6'1, the force of the latter against the diaphragm El being adjustable, if desired, by an adjusting screw, not shown, in cap 88.

The high pressure passageway 5i has two inlets: an upper port 70 for the pressure line 20 leading from the inlet end I1 ofthe Venturi tube I6; and a lower port I2 for a conduit ll leading from the eflluent line Ii above the shutoff valve I3. The two ports I and I2 are preferably machined to provide valve seats for the disc valve I3 and are placed in adjacent and opposing relationship so that a small movement of the disc valve (3 will instantaneously open one port and close the other. The valve I3 is mounted on a valve rod I4, extending through the wall of the secondary, casing 50, and the partition 55, as shown, into the low pressure passageway 52 to a point sufiiciently close to the plug valve 60 operable in the waste port 59 between the low pressure flow passage 52 and the waste compartment 54 to lift the plug valve60 off its valve seat 59 when the disc valve I3 is raised to close the upper port I6 and open the lower port I2 but to permit the plug valve 60 to rest firmly on the valve seat 59 when the disc valve 13 is lowered to close the lower port I2 and to open the upper port Hi. It is preferred that the valve rod I4 not be joined to the plug valve 66 as it is desired that the plu valve 60 may be opened, as by movement of float 26, without changing the setting of the disc valve 13. A lever I5, bearing on a suitable fulcrum, such as I6, is pivotally connected to the valve rod I4, as at 11. The free end of the lever I6 is connected by means of cable I8 to the tail rod I9 of the piston in hydraulic cylinder 22 in such a manner that when the hydraulic power apparatus 22 closes the shutoff valve II the lever I is moved to open the lower port 12 and close the upper port I0. It is preferred that the lever I5 be provided with a weight 80 at the free end thereof, or other suitable means, to positively move the lever in the reverse direction when the valve I3 is moved to open position and thus to close the lower port 12 and open the upper port I0. It is preferred that a tight fitting gland 8| close the aperture through which the disc valverod I4 enters the secondary casing 50 in order to provide a water-tight joint at this point. Sufiiclent force is available for moving the lever I5 to permit such a construction.

The plug valve 60 is moved by means of a valve rod 85 to which it is firmly attached. The rod 85 extends out through the wall of the secondary casing 50 through a packing gland 66 and is pivotally attached to a lever 81 as at 66. The lever 81 is pivoted at any suitable fulcrum, such as at 89, and is preferably provided with a weight 96 at the free end in order to normally close the plug valve 60. A float rod 9| is affixed at one end to the float 26 in the reservoir I2 and the other end engages the free end of the level 61, by any suitable means, such as a collar 92 so that the rising of float 26 above the predetermined level 21 (Figure 1) will gradually lift the plug valve 60 off its seat 59, thereby permitting fiow of liquid from the low pressure passage 52 into the waste compartment 54 and thence out through outlet valve and outlet pipe 63. The outlet valve 64 will be opened at this point, as hereinafter described. 0n the reverse movement of the float 26, in dropping below the predetermined liquid level 21 in the reservoir, the plug a valve 69 is again seated on the valve seat 59 and the communication between the low pressure flow passage 52 and the waste compartment to is closed. .As indicated above, the plug valve 30 1 is also lifted from its seat by the movement oi the disc valve rod M which opens the lower inlet port I2 and closes the upper inlet port Hi.

The normal operation of the flow controller herein described (that is, when the shutofi valve 13 is opened so that flow will pass through the Venturi tube I6, fiow control valve I5, and thence to reservoir I2, which is not filled to the predetermined level 21) is the same as that of the Adelson controller. In such normal operation disc valve lever 15 will be lowered, thereby closing the lower port 12 and opening the upper port I0. Also in normal operation the float 28 would be below the predetermined upper level 21 of water in the reservoir I2 so that the plug valve is also closed. Water, under the pressure existing at the mouth ll of the Venturi tube, passes through the first, or high, pressure conduit 20, the upper port III, into the high pressure passage 5|, and thence through pipe 6I, into high pressure chamber 35 of the actuator I9, whereby the pressure in chamber 35 will tend to raise the weighted diaphragm 34 and close fiow control valve I5. Such flow of water can escape from the high pressure chamber 35, through thebypass 46, and the orifice 44, into low pressure pipe 2 I, through rate setter valve 46, and into the throat I8 of the Venturi tube. Three pressure values, as indicated above, are

- used in the constant differential systemnamely, upstream of the Venturi tube; an intermediate pressure lower than upstream; and throat pressure of the venturi. The low pressure chamber 36 communicates with the zone of intermediate pressure between the two orifices l4 and 46 and thus while technically known as the low pressure" chamber it is actually subject to the intermediate pressure of the constant differential system. Of these pressures only upstream and intermediate are balanced by the amount of weight placed on the diaphragm whose high and low pressure chambers connect to upstream and intermediate pressurezones-that is, across the fixed or primary orifice 44. Such a structure provides for a constant differential in the pressures between the high pressure chamber 35 and the low pressure chamber 36 regard-less of the actual difference in pressure between the mouth I! and throat I8 of the Venturi tube.

The constant diiTerential controller, and its operation above described, is not claimed herein, as my invention relates to means for automatically modifying the intermediate pressure of the Adelson system so that a new summation of losses through valve rate setter 46 and orifice 44 will be balanced by a new Venturi head upon the occurrence of certain outside conditions. Such outside conditions may be the raising or lowering Upon the of the liquid level in the reservoir I2. termination of the outside conditions the original values are reestablished and the original Venturi head used for control.

It is obvious that in normal operation there will be no possible flow from the low pressure chamber 36, through the waste chamber 64, and the waste pipe 63, as the plug valve 60 will be tightly closed. The waste valve 66 will also be closed as water in the reset diaphragm chamber 53 will be under the same intermediate pressure as exists in the low pressure chamber 66, as

chamber 63 is open to the low pressure chamber 36, through the orifice 56, and low pressure passage l2, and pipe 62 There will be no counterbalancing pressure in the waste chamber 54, so

that the pressure under the diaphragm I! (being Closing of shutoff valve i3 moves the tail rod 7 191:0 which cable It isattached, and raises lever 15, thereby raising the disc valve rod 14 to move the disc valve away from the lower port I2 and close the upper port 10.- The movement of the disc valve rod 14 also liftsthe plug valve 30 from its valve seat or orifice 59, thus providing passage for water from above the shutofl valve l3 through the second high pressure line H, lower port 12, high pressure passage 5|, pipe 6|, high pressure chamber 36, orifice 44, low pressure chamber 36, pipe 62, low pressurepassage l2, orifice 59, chamber 54, through valve 63, and pipe 63, to line H. With valve l3 closed, the tube I 6 and line H following valve I3 are under a negative head or at least a much lower head than is stopped ofi by valve l3. This head provides the gradient for the fiow traced above.

It will be understood that by the raising of the 'plug valve 6|! 012 its seat a passage for the escape the passage to waste line 63. This new course of flow from low pressure chamber 36, being larger. than the orifice of the rate setter valve 48, causes less back-pressure in the low pressure chamberv 35, so that a new diil'erential is established between high and low pressure chambers 35 and 36. This new diilferential is due to the fact that the size of the above flow is large in relation to the size of orifice 44 and that in rate setter valve 46. Thus there is little or no back pressure on low pressure chamber 36, so that there will be a considerable diiferential, or drop in pressures, between high pressure chamber 35 and low pressure chamber .36-thus providing a sufllcient force'to close the control valve l5 and keep it closed. When the shutoff valve I3 is again opened, the tail rod' 19 will rise and permit the lever to drop, thereby moving disc valve I3 from across the upper port 10 to close the lower port 12 and permitting plug valve 60 to drop and again become seated in its associated orifice 53.

same, as will the pressures in the two pressure chambers II and It. The eilect or weight 43 on diaphragm 34, now unopposed by pressure, will be to permit it to slowly drop thereby opening flow control valve II. The movement of the diaphragm, however, will be slow as both low pres- At this point there will be no appreciable flow through the Venturi tube as the valve I 5 is closed, although there may be a little leakage around the control valve l5, as such valves ordinarily are constructed to permit a small flow therethrough. Obviously, from the means shown, the change from one flow from one high pressure line 'to another will be instantaneous and at the moment of opening the upper port Ill, and closing the lower port 12, the actuator will be filled with liquid so that a sharp movement of the diaphragm, with resultant rapid opening of the flow control valve I5 is impossible. Also, upon the movement of lever 15 to close lower port 12, and open port 10, the plug valve 60 will be permitted to become reseated on its valve seat 59, thereby terminating the secondary flow from low pressure chamber 36 through waste compartment 54, thus directing all of the bypass flow through the fixed orifice 44, low pressure line 2|, and its restricted orifice 46. The pressures in both high pressure conduit 20 and intermediate pressure conduit 2| will therefore be substantially the.

sure chamber 36, and high pressure chamber 35, and connecting passageways, will be full of water. The movement of the diaphragm, therefore, can be accomplished only as water is displaced from high pressure chamber 35, through restricted orifice 44, into low pressure chamber 38, thus providing a very gradual opening of flow control valve l5, due to this dash pot action. It is of course obvious that regardless of how rapidly shutofl valve i3 is opened, normal operating conditions are set up gradually because of the gradual opening of control valve i5. The amount of opening of valve I5 is automatically limited when flow therethrough sets up a Venturi head that again equals the sum of the losses through fixed orifice 44 and rate-setter valve 48.

The operation of my reset device from the liquid level in the clearwell l2, reaching a predetermined point, such as 21, is somewhat similar in eilect;

However, the opening or closing of the valve l5 in this event is controlled entirely by the position of the float 26, while in the above described actuation by opening or closing of shutoii valve i3, the action is as instantaneous as the dash pot effect of the actuator ill will permit. As the fioat 26 rises, the collar 92 engagesthe lever 81, thereby gradually lifting needle valve 60 from its associated orifice. It will be obvious that with a tapered plug valve, or one of other variable diameter, the amount of flow through the orifice 59 will be proportional to the positionof the valve plug 60. As

the valve 60 is 1ifted,the pressure in the waste chamber 54, and reset diaphragm-chamber 53, will be equalized, and the valve 64 will be opened by spring 61, thus permitting a flow from the waste chamber 54. This modification of the intermediate pressure through loss of water through waste line 63, rather than the smaller orifice of rate setter valve 46, creates a new differential between the pressures in the pressure chambers 35 and 36. However, the flow from the low pressure chamber 36 will be controlled by the degree to which the orifice 59 is opened, so that as the valve 60 is lifted the pressure differential between high pressure chamber 35 and low pressure chamber 36 will gradually increase, thus aifording a gradual closing of the flow control valve l5. The closing of the flow control valve i5 will be directly proportional to the rise of the float 23, as the free space opened by the plug valve 60 will vary according to the amount of movement'of that valve. This not only permits a gradual closing of the flow control valve l5 but also a gradual opening thereof at such time as the float 23 is lowered, thereby closing the needle valve 60, as herein described. As water is withdrawn from the reservoir l2, the liquid level will fall below the predetermined point, the fioat- 26 will drop, thereby lowering the lever 81 and again seating the plug valve 60 on valve seat 58. The closing of the needle valve 60 will terminate flow from the pressure chamber 36 to waste chamber 54 and thence to waste, thus gradually reestablishlng the normal operation of the actuator l1.

It is apparent that my reset, or modification, of control is through a modification of the intermediate pressure of the constant difierential system. It can also operate on the old system of a high and low pressure only (no bypass flow around 11 the diaphragm of the controller) by maintaining the high pressure constantly and withdrawing water from the low pressure side to establish a new differential.

It is believed obvious that the device of my invention, which in its preferred form is directed to the closing of the fiow control valve II, by either the closing of the shutofl valve I! or the rise of liquid level in the reservoir I2 to a predetermined point, can be adapted to do either alone. Thus my invention in its preferred form combines the two controls in one compact and simple mechanism but if, for any reason, it is desired to use one control to the exclusion of the other it can readily be done by eliminating one or the other feature, without affecting the operation of the control which remains.

It might be noted that the plug valve 60 can be conical, as shown, which provides for a uniform progression from closed to fully open position. If a variable progression is desired such as rapid initial opening of orifice 58, followed by more gradual opening to fully open position, or a very gradual initial opening followed by a more rapid one, it can be easily secured by changing the form of the plug, as for instance, to parabolic form.

It will also be obvious that my reset device can be adapted to a battery of flow systems such as that found in many municipal filter plants where a battery of filters is necessary, so that each actuator reset device can be set to operate to modify or reset its controller at different levels in the liquid in the clearwell. Thus flow through some of the filters can be terminated when the level reaches some intermediate point and others successively as the liquid level rises.

It is obvious that my reset device provides for gradual increases and decreases in flow through the controlled opening of fiow control valve l5, thereby avoiding surging and the dangers inherent thereto. It is also obvious that the actuator and the reset device are at all times ready to control or modify the control without delay due to inertia or other static conditions.

Various modifications of the device herein described will be obvious to those skilled in the art so that it is intended that the above description shall be deemed as illustrative of my invention and not as a limitation thereof.

I claim:

1. An actuator adapted for use in a filter system including a main conduit. a shutoff valve in said conduit, and a pressure differential creating member in said conduit, said actuator comprising a casing, a diaphragm dividing said casing into two chambers. means ada ted to operatively join said diaphragm to a device to be ac'tuated. a first pressure port adapted to connect one of said chambers with a point of high pressure in the'pressure differential creating member, a second pressure port adapted to connect the other chamber with a point of low pressure in said pressure differential creating member, an inlet into said first chamber adapted to connect the same to a point in said main conduit on the upstream side of said shutoff valve, an outlet from said second chamber, a normally closed valve on said outlet, means effective on closing of said shutofl valve to position said valve means to open said inlet and close said first pressure port, and means effective on opening of said inlet to open said valve on said outlet.

2. An actuator adapted for use in a flow system including a main conduit, a shutoff valve in said conduit, 9. pressure differential creating member in said conduit and a basin receiving liquid from said conduit; said actuator comprising a casing, a diaphragm dividing said casing into two chambers, means adapted to operatively join said diaphragm to a device to be actuated, a first pressure port adapted to connect one of said chambers with a point of high pressure in the pressure differential creating member, a second port adapted to connect the other chamber with a point of low pressure in said pressure differential creating member, an inlet into said first chamber adapted to connect the same to a point in the main conduit on the upstream side of said shutoff valve, inlet valve means associated with said inlet and said first pressure port normally closing the former and opening the latter, an outlet from said second chamber, a normally closed outlet valve on said outlet, means efiective on closing of said shutoff valve to position said inlet valve means to open said inlet and close said first pressure port and to open said outlet valve, a member sensitive to change of the liquid level in said basin, and means operatively connecting said last mentioned member to said outlet valve to open said outlet valve upon the liquid level in said basin reaching a predetermined point.

3. In a flow system including the combination of a main conduit, a shutoff valve in said conduit, a pressure difi'erential creating device in said conduit, 9. flow control valve in said conduit, and a basin receiving liquid from said conduit, an improved actuator for said fiow control valve comprising a casing, a diaphragm dividing said casing into two chambers, said diaphragm being joined to said fiow control valve, a first pressure conduit connecting one of. said chambers with the high pressure side of said pressure differential creating means, a second pressure conduit connecting the other of said chambers with the low pressure side of the pressure differential creating means, a weight normally forcing said diaphragm from said second chamber into said first chamber, a communication provided with a fixed orifice between said chambers, a second and smaller orificein said second pressure conduit, an inlet into said first chamber communicating with said main conduit above said shutoff valve, an outlet from said second chamber, valve means normally closing said inlet and opening said first pressure conduit and operable on the closing of said shutoff valve to open said inlet and to close the first pressure conduit, valve means normally closing said outlet and operable on the closing of said shutoff valve to open said outlet, and means operable by the level of liquid in said receiving basin to independently position the valve means in said outlet.

4. In a constant diflerential type actuator for a flow control valve, said actuator including a high pressure chamber, a low pressure chamber, a flexible diaphragm separating said chambers, an inlet into said high pressure chamber, an outlet from said low pressure chamber, a communication between said chambers having a cross-sectional area less than that of said inlet into said high pressure chamber, and an orific'e in said outlet from said low pressure chamher having a cross-sectional area less than that of said communication, means for automatically setting the actuatorto control in response to a change in an outside condition which comprises means for modifying the diiference in pressure between said chambers independently of any change in the normal pressure difference between them,sjaid.means including a second outlet from said low pressure chamber, a valve in said second outlet, and means to position said device to be actuated, and a restricted passageway between the two sides of said pressure differential sensitive member, the combination with said pressure differential sensitive member of a secondary inlet into'said bypass on the high pressure side of said pressure differential sensitive member from a source of hydraulic pressure effective to create pressure irrespective of pressure conditions in said Venturi tube, an outlet from the low pressure side of said pressure differential sensitive member, valve means in said secondary inlet and said outlet normally closing the same and means operable'to open said valve means.

6. In combination with a control valve actuator adapted to control flow in a filter system, said system including a filter, a filtered liquid receiving basin, a main conduit for filtered liquid'from said filter to said basin, a shutoff valve in said conduit, and a flow control valve in said conduit, 'said actuator including a casing, a diaphragm dividing said easing into two chambers, a first pressure conduit connecting one of said chambers with a high pressure area in said system, a second pressure conduit connecting the other of said chambers with'a low pressure area in said system, a pressure means normally tending to force said diaphragm into said first chamber, a bypass from said ifilSt chamber to said second chamber, an orifice in said bypass, and a second orifice in said second pressure conduit: an improved means for modification of normal operation of said actuator to close said flow control valve upon the termination of flow through said system and independently upon the filling of said basin, said means comprising a secondary inlet connecting said first chamber with said conduit on the upstream side of said shutoff valve, an outlet from said second chamber, valve means normally closing said inlet, separate valve means normally closing said outlet, means operable by the closing of said shutoff valve to open said valve meansin said secondary inlet and in said outlet and to close said first pressure conduit, a float in said basin, and means operable by the raising of said float above a predetermined level to open said valve means in said outlet.

7. An actuator. adapted for'use in a flow system including a pressure differential creating member comprising a casing, a diaphragm dividing said easing into two chambers and adapted to be operatively joined to a device to 'be actuated. a first pressure inlet adapted to connect one of said chambers with a point of high pressure in the pressure differential creating member. a second pressure inlet adapted to connect the other chamber with a point. of low,

pressure in said differential creating member, a restricted communication between said chambers. and means for modifying operation of said diapbrac'm comprising a third pressure inlet adapted to connect sa d first chamber o an independent point of pressure, a valve meansnormally closing said third pressure inlet and opening said first pressure inlet arid operable on termination of flow through said system to open said third pressure inlet and to close the first pressure inlet.

8. An actuator'adapted for use in a flow system which includes a pressure differential creating member, comprising a casing, a diaphragm dividing. said easing into, two chambers and adapted to be operatively connected to' a device to be actuated, a first pressure inlet adapted to connect one of said chambers with a point of high pressure in the pressure difierential creating member, a second pressure inlet adapted to connect the other chamber with a point of low prcssurein said diii'erential creating member, a restricted communication between said chambers, a rate setter orifice in said second pressure inlet, and means for modifying operation of said diaphragm independently of the pressure difference between said points of high and low pressure, comprising an outlet from the other of said chambers, a valve in said outlet normally closing the same and means to position said valve to open said outlet.

9. An actuator for a flow system that includes a pressure differential creating member, said actuator comprising a casing, a diaphragm dividing said casing into two chambers and adapted to be operatively connected to a device to be actuated, a first pressure inlet adapted to connect one of said chambers with a point of high pressure in the pressure differential creating member,.a second pressure inlet adapted'to connect the other chamber with .a point of low pressure in said differential creating member,

a restricted communication between said chambers, a restriction in said second pressure inlet, a means for positioning the device to be operated independently of flow through said pressure differential creating member, said means comprising a second casing, a diaphragm dividing said easing into two compartments. a eonstantly open conduit connecting said low pressure chamber'with a first of said compartments, an inletinto the second of said compartments from said low pressure chamber, a variably shaped plug valve in said inlet, an outlet from said second compartment, a balanced valve means in said outlet, mechanical pressure means tending to normally (men said outlet valve, said outlet valve being joined to said last mentioned diaphragm in such manner that pressure on said diaphragm from said first compartment tends to close said valve, and means to independently position said plug valve.

10. In a constant differential type actuator for a fiow control valve, said actuator including a high pressure chamber, a low pressure chamher, a flexible diaphragm separating said chamhers. an inlet into said high pressure chamber, an outlet from said low pressure chamber, a communicat on between said chambers having a cross-sectional area lessthan that of said inlet into said-high pressure chamber, and an orifice in said outlet from said low pressure chamber having a cross-sectional area less than that of said communication, means for automatically setting the actuator to control in response to a change in an outside condition which comprises means for modifying the difference in pressure between said chambers independently of any change in the conditions creating the normalpressure difference between them. said means second inlet and opening said first inlet into said high pressure chamber, and means to position said valve means in response to said outside condition.

11. In a constant diilerentlal type actuator for a now control valve, said actuator including a high pressure chamber, a low pressure chamber, a flexible diaphragm separating said chambers, an inlet into said high pressure chamber, an outlet from said low pressure chamber, a communication between said chambers having a crosssectional area less than that of said inlet into said high pressure chamber, and an oriflc'e in said outlet from said low pressure chamber having a cross-sectional area less than that of said communication, means for automatically setting the actuator to control in response to a change in an outside condition which comprises means for modifying the difi'erence in pressure between said chambers independently of any change in the conditions creating the normal pressure difference between them, said means including a second inlet into said high pressure chamber, valve means normally opening said first inlet 16 into said high pressure chamber and closina said second inlet, a second outlet from said low pressure chamber, a valve in said second outlet, and means to position said valves in response to said outside condition.

WALTER J. HUGHES.

REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 840,877 Steedman Jan. 8, 1907 1,156,855 Akans Oct. 12, 1915 1,934,713 Hughes Nov. 14, 1933 1,936,373 Adelson Nov. 21, 1933 2,223,623 Koupal et al Dec. 3, 1940 2,292,703 Lawler Aug. 11, 1942 2,347,837 Morrison May 2, 1944 FOREIGN PA'I'EN'IB Number Country Date 539,068 Great Britain Aug. 27, 1941 

